Polarization-multiplexed optics for head-mounted display systems

ABSTRACT

The present disclosure is related generally to techniques for improving the performance and efficiency of display systems, such as laser scan beam display systems or other types of display systems (e.g., micro-displays) of an HMD system or other device. Display systems of the present disclosure may utilize polarization multiplexing that allow for improved optimization of diffraction optics. In at least some implementations, a display system may selectively polarize light dependent on wavelength (e.g., color) or field of view. An optical combiner may include polarization sensitive diffractive optical elements that are each optimized for a subset of colors or portions of an overall field of view, thereby providing improved correction optics for a display system.

BACKGROUND Technical Field

The present disclosure generally relates to display systems, and more particularly, to improving the efficiency and performance of display systems.

Description of the Related Art

One current generation of virtual reality (“VR”) experiences is created using head-mounted displays (“HMDs”), which can be tethered to a stationary computer (such as a personal computer (“PC”), laptop, or game console), combined and/or integrated with a smart phone and/or its associated display, or self-contained. Generally, HMDs are display devices, worn on the head of a user, which have a small display device in front of one (monocular HMD) or each eye (binocular HMD). The display units are typically miniaturized and may include CRT, LCD, Liquid crystal on silicon (LCoS), OLED technologies, or laser scan beam displays, for example. A binocular HMD has the potential to display a different image to each eye. This capability is used to display stereoscopic images.

Demand for displays with heightened performance has increased with the development of smart phones, high-definition televisions, as well as other electronic devices. The growing popularity of virtual reality and augmented reality systems, particularly those using HMDs, has further increased such demand. Virtual reality systems typically envelop a wearer's eyes completely and substitute a “virtual” reality for the actual or physical view (or actual reality) in front of the wearer, while augmented reality systems typically provide a semi-transparent or transparent overlay of one or more screens in front of a wearer's eyes such that actual view is augmented with additional information, and mediated reality systems may similarly present information to a viewer that combines real-world elements with virtual elements.

For augmented reality applications, a see-through optical combiner may be provided which combines and simultaneously delivers a virtual image and the real world to the user's eyes. Once such technology used for an optical combiner utilizes diffractive optics, which provide high efficiency, are readily able to be manufactured, among other advantages. However, it can be a significant challenge to design diffractive optical combiners that provide a high level of correction over an entire field of view and/or over multiple wavelengths.

BRIEF SUMMARY

A head-mounted display system may be summarized as including a support structure; and a display system coupled to the support structure, the display system including a display light source; a selective polarizer optic operative to receive light from the display light source, and to output light of a first color in a first polarization state and light of a second color in a second polarization state, the second polarization state orthogonal to the first polarization state; and an optical combiner positioned to receive light from the selective polarizer optic and to provide images to an eye of a viewer, the optical combiner including a first polarization sensitive diffractive optical element (PSDOE) that includes a first diffraction pattern that diffracts light of the first polarization state and passes light of the second polarization state without diffraction, the first diffractive pattern providing optimized correction for the first color; and a second PSDOE that includes a second diffraction pattern that diffracts light of the second polarization state and passes light of the first polarization state without diffraction, the second diffractive pattern providing optimized correction for the second color. Each of the selective polarizer optic, the first PSDOE, and the second PSDOE may include a multi-twist retarder. At least one of the selective polarizer optic, the first PSDOE, and the second PSDOE may include a multi-twist retarder. At least one of the selective polarizer optic, the first PSDOE, and the second PSDOE may include liquid crystal material. A selective polarizer optic may be operative to output light of a third color in the second polarization state, and the second diffractive pattern may provide optimized correction for the second color and the third color. The first color may be red and the second and third colors are green and blue, respectively. The first color may be red, and the second color is green or blue. The optical combiner may include an in-coupler and an out-coupler. The support structure may include an eyeglasses lens. The display light source may include a laser scan beam system or a micro-display.

A head-mounted display system may be summarized as including a support structure; and a display system coupled to the support structure, the display system including a display light source; a selective polarizer optic operative to receive light from the display light source that has a total field of view, and to output light of a first field of view portion of the total field of view in a first polarization state and light of a second field of view portion of the total field of view in a second polarization state, the second polarization state orthogonal to the first polarization state; and an optical combiner positioned to receive light from the selective polarizer optic and to provide images to an eye of a viewer, the optical combiner including a first polarization sensitive diffractive optical element (PSDOE) that includes a first diffraction pattern that diffracts light of the first polarization state and passes light of the second polarization state without diffraction, the first diffractive pattern providing optimized correction for the first field of view portion; and a second PSDOE that includes a second diffraction pattern that diffracts light of the second polarization state and passes light of the first polarization state without diffraction, the second diffractive pattern providing optimized correction for the second field of view portion. The first field of view portion may include an angular range of 0 degrees to M degrees, and the second field of view portion comprises an angular range of M degrees to N degrees, where N is the angular range of the field of view of the HMD system, and M is less than N. The first field of view portion and the second field of view portion may combine to form the total field of view. The first field of view portion may be surrounded by the second field of view portion. The first field of view portion may include a first half of the total field of view, and the second field of view portion may include a second half of the total field of view. The first field of view portion and the second field of view portion may at least partially overlap each other. Each of the selective polarizer optic, the first PSDOE, and the second PSDOE may include a multi-twist retarder. At least one of the selective polarizer optic, the first PSDOE, and the second PSDOE may include a multi-twist retarder. At least one of the selective polarizer optic, the first PSDOE, and the second PSDOE may include liquid crystal material. The optical combiner may include an in-coupler and an out-coupler. The support structure may include an eyeglasses lens. The display light source may include a laser scan beam system or a micro-display.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

In the drawings, identical reference numbers identify similar elements or acts. The sizes and relative positions of elements in the drawings are not necessarily drawn to scale. For example, the shapes of various elements and angles are not necessarily drawn to scale, and some of these elements may be arbitrarily enlarged and positioned to improve drawing legibility. Further, the particular shapes of the elements as drawn, are not necessarily intended to convey any information regarding the actual shape of the particular elements, and may have been solely selected for ease of recognition in the drawings.

FIG. 1 is a schematic diagram of a networked environment that includes one or more systems suitable for performing at least some techniques described in the present disclosure.

FIG. 2 is a diagram illustrating an example environment in which at least some of the described techniques are used with an example head-mounted display device that is tethered to a video rendering computing system and providing a virtual reality display to a user.

FIG. 3 is a front pictorial diagram of an example HMD device having binocular display subsystems.

FIG. 4 illustrates a top plan view of an HMD device having binocular display subsystems and various sensors, according to an example embodiment of the present disclosure.

FIG. 5 is a schematic block diagram of a display system that includes a spatially varying polarizer, according to one non-limiting illustrated implementation.

FIG. 6 is a schematic diagram of a scan beam display system, according to one non-limiting illustrated implementation.

FIG. 7 is a schematic diagram of a scan beam display system that includes a spatially varying polarizer that is selectively adjusted based on a user's determined or inferred gaze location, according to one non-limiting illustrated implementation.

FIG. 8 is a schematic diagram of a display system that includes a waveguide-based optical system and a spatially varying polarizer, according to one non-limiting illustrated implementation.

FIG. 9 is a schematic diagram of a display system that includes a waveguide-based optical system that utilizes polarization multiplexing over wavelength, according to one non-limiting illustrated implementation.

FIG. 10 is a schematic diagram of a display system that includes a waveguide-based optical system that utilizes polarization multiplexing over a field of view, according to one non-limiting illustrated implementation.

FIG. 11A is a schematic diagram of a total field of view of an HMD system that is comprised of a first field of view portion surrounded by a second field of view portion, wherein an optical combiner of the HMD system includes a first polarization sensitive diffractive optical element that is optimized for the first field of view portion and a second polarization sensitive diffractive optical element that is optimized for the second field of view portion.

FIG. 11B is a schematic diagram of a total field of view of an HMD system that is comprised of a first field of view portion positioned adjacent a second field of view portion, wherein an optical combiner of the HMD system includes a first polarization sensitive diffractive optical element that is optimized for the first field of view portion and a second polarization sensitive diffractive optical element that is optimized for the second field of view portion.

DETAILED DESCRIPTION

In the following description, certain specific details are set forth in order to provide a thorough understanding of various disclosed implementations. However, one skilled in the relevant art will recognize that implementations may be practiced without one or more of these specific details, or with other methods, components, materials, etc. In other instances, well-known structures associated with computer systems, server computers, and/or communications networks have not been shown or described in detail to avoid unnecessarily obscuring descriptions of the implementations.

Unless the context requires otherwise, throughout the specification and claims that follow, the word “comprising” is synonymous with “including,” and is inclusive or open-ended (i.e., does not exclude additional, unrecited elements or method acts).

Reference throughout this specification to “one implementation” or “an implementation” means that a particular feature, structure or characteristic described in connection with the implementation is included in at least one implementation. Thus, the appearances of the phrases “in one implementation” or “in an implementation” in various places throughout this specification are not necessarily all referring to the same implementation. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more implementations.

As used in this specification and the appended claims, the singular forms “a,” “an,” and “the” include plural referents unless the context clearly dictates otherwise. It should also be noted that the term “or” is generally employed in its sense including “and/or” unless the context clearly dictates otherwise.

The headings and Abstract of the Disclosure provided herein are for convenience only and do not interpret the scope or meaning of the implementations.

The present disclosure relates generally to techniques for improving the performance and efficiency of display systems, such as laser scan beam display systems or other types of display systems (e.g., micro-displays). For many types of optics, such as diffraction optics used in augmented reality (AR) systems, it may be difficult to provide correction over an entire field of view or over a broad range of wavelengths (e.g., red, green, blue). Display systems of the present disclosure may utilize polarization multiplexing that allow for better optimization of diffraction optics. In at least some implementations, a display system may polarize light dependent on wavelength or field of view. An optical combiner may include multiple polarization sensitive diffractive optical elements that are each optimized for a subset of colors or portions of an overall field of view, thereby providing improved correction optics for a display system.

Initially, an example head-mounted display device application for the techniques described herein is discussed with reference to FIGS. 1-4 . Then, with reference to FIGS. 5-11 , example implementations of display systems that include features of the present disclosure are discussed.

Example Head-Mounted Display System and Environment

FIG. 1 is a schematic diagram of a networked environment 100 that includes a local media rendering (LMR) system 110 (e.g., a gaming system), which includes a local computing system 120 and display device 180 (e.g., an HMD device with two display panels) suitable for performing at least some techniques described herein. In the depicted embodiment of FIG. 1 , the local computing system 120 is communicatively connected to display device 180 via transmission link 115 (which may be wired or tethered, such as via one or more cables as illustrated in FIG. 2 (cable 220), or instead may be wireless). In other embodiments, the local computing system 120 may provide encoded image data for display to a panel display device (e.g., a TV, console or monitor) via a wired or wireless link, whether in addition to or instead of the HMD device 180, and the display devices each includes one or more addressable pixel arrays. In various embodiments, the local computing system 120 may include a general purpose computing system; a gaming console; a video stream processing device; a mobile computing device (e.g., a cellular telephone, PDA, or other mobile device); a VR or AR processing device; or other computing system.

In the illustrated embodiment, the local computing system 120 has components that include one or more hardware processors (e.g., centralized processing units, or “CPUs”) 125, memory 130, various I/O (“input/output”) hardware components 127 (e.g., a keyboard, a mouse, one or more gaming controllers, speakers, microphone, IR transmitter and/or receiver, etc.), a video subsystem 140 that includes one or more specialized hardware processors (e.g., graphics processing units, or “GPUs”) 144 and video memory (VRAM) 148, computer-readable storage 150, and a network connection 160. Also in the illustrated embodiment, an embodiment of an eye tracking subsystem 135 executes in memory 130 in order to perform at least some of the described techniques, such as by using the CPU(s) 125 and/or GPU(s) 144 to perform automated operations that implement those described techniques, and the memory 130 may optionally further execute one or more other programs 133 (e.g., to generate video or other images to be displayed, such as a game program). As part of the automated operations to implement at least some techniques described herein, the eye tracking subsystem 135 and/or programs 133 executing in memory 130 may store or retrieve various types of data, including in the example database data structures of storage 150, in this example, the data used may include various types of image data information in database (“DB”) 154, various types of application data in DB 152, various types of configuration data in DB 157, and may include additional information, such as system data or other information.

The LMR system 110 is also, in the depicted embodiment, communicatively connected via one or more computer networks 101 and network links 102 to an exemplary network-accessible media content provider 190 that may further provide content to the LMR system 110 for display, whether in addition to or instead of the image-generating programs 133. The media content provider 190 may include one or more computing systems (not shown) that may each have components similar to those of local computing system 120, including one or more hardware processors, I/O components, local storage devices and memory, although some details are not illustrated for the network-accessible media content provider for the sake of brevity.

It will be appreciated that, while the display device 180 is depicted as being distinct and separate from the local computing system 120 in the illustrated embodiment of FIG. 1 , in certain embodiments some or all components of the local media rendering system 110 may be integrated or housed within a single device, such as a mobile gaming device, portable VR entertainment system, HMD device, etc. In such embodiments, transmission link 115 may, for example, include one or more system buses and/or video bus architectures.

As one example involving operations performed locally by the local media rendering system 120, assume that the local computing system is a gaming computing system, such that application data 152 includes one or more gaming applications executed via CPU 125 using memory 130, and that various video frame display data is generated and/or processed by the image-generating programs 133, such as in conjunction with GPU 144 of the video subsystem 140. In order to provide a quality gaming experience, a high volume of video frame data (corresponding to high image resolution for each video frame, as well as a high “frame rate” of approximately 60-180 of such video frames per second) is generated by the local computing system 120 and provided via the wired or wireless transmission link 115 to the display device 180.

It will also be appreciated that computing system 120 and display device 180 are merely illustrative and are not intended to limit the scope of the present disclosure. The computing system 120 may instead include multiple interacting computing systems or devices, and may be connected to other devices that are not illustrated, including through one or more networks such as the Internet, via the Web, or via private networks (e.g., mobile communication networks, etc.). More generally, a computing system or other computing node may include any combination of hardware or software that may interact and perform the described types of functionality, including, without limitation, desktop or other computers, game systems, database servers, network storage devices and other network devices, PDAs, cell phones, wireless phones, pagers, electronic organizers, Internet appliances, television-based systems (e.g., using set-top boxes and/or personal/digital video recorders), and various other consumer products that include appropriate communication capabilities. The display device 180 may similarly include one or more devices with one or more display panels of various types and forms, and optionally include various other hardware and/or software components.

It will also be appreciated that, while various items are illustrated as being stored in memory or on storage while being used, these items or portions of them may be transferred between memory and other storage devices for purposes of memory management or data integrity. Thus, in some embodiments, some or all of the described techniques may be performed by hardware that include one or more processors or other configured hardware circuitry or memory or storage, such as when configured by one or more software programs and/or data structures (e.g., by execution of software instructions of the one or more software programs and/or by storage of such software instructions and/or data structures). Some or all of the components, systems and data structures may also be stored (e.g., as software instructions or structured data) on a non-transitory computer-readable storage medium, such as a hard disk or flash drive or other non-volatile storage device, volatile or non-volatile memory (e.g., RAM), a network storage device, or a portable media article to be read by an appropriate drive (e.g., a DVD disk, a CD disk, an optical disk, etc.) or via an appropriate connection. The systems, components and data structures may also in some embodiments be transmitted as generated data signals (e.g., as part of a carrier wave or other analog or digital propagated signal) on a variety of computer-readable transmission mediums, including wireless-based and wired/cable-based mediums, and may take a variety of forms (e.g., as part of a single or multiplexed analog signal, or as multiple discrete digital packets or frames). Such computer program products may also take other forms in other embodiments. Accordingly, the present invention may be practiced with other computer system configurations.

FIG. 2 illustrates an example environment 200 in which at least some of the described techniques are used with an example HMD device 202 that is coupled to a video rendering computing system 204 via a tethered connection 220 (or a wireless connection in other embodiments) to provide a virtual reality display to a human user 206. The user wears the HMD device 202 and receives displayed information via the HMD device from the computing system 204 of a simulated environment different from the actual physical environment, with the computing system acting as an image rendering system that supplies images of the simulated environment to the HMD device for display to the user, such as images generated by a game program and/or other software program executing on the computing system. The user is further able to move around within a tracked volume 201 of the actual physical environment 200 in this example, and may further have one or more I/O (“input/output”) devices to allow the user to further interact with the simulated environment, which in this example includes hand-held controllers 208 and 210.

In the illustrated example, the environment 200 may include one or more base stations 214 (two shown, labeled base stations 214 a and 214 b) that may facilitate tracking of the HMD device 202 or the controllers 208 and 210. As the user moves location or changes orientation of the HMD device 202, the position of the HMD device is tracked, such as to allow a corresponding portion of the simulated environment to be displayed to the user on the HMD device, and the controllers 208 and 210 may further employ similar techniques to use in tracking the positions of the controllers (and to optionally use that information to assist in determining or verifying the position of the HMD device). After the tracked position of the HMD device 202 is known, corresponding information is transmitted to the computing system 204 via the tether 220 or wirelessly, which uses the tracked position information to generate one or more next images of the simulated environment to display to the user.

There are numerous different methods of positional tracking that may be used in the various implementations of the present disclosure, including, but not limited to, acoustic tracking, inertial tracking, magnetic tracking, optical tracking, combinations thereof, etc.

In at least some implementations, the HMD device 202 may include one or more optical receivers or sensors that may be used to implement tracking functionality or other aspects of the present disclosure. For example, the base stations 214 may each sweep an optical signal across the tracked volume 201. Depending on the requirements of each particular implementation, each base station 214 may generate more than one optical signal. For example, while a single base station 214 is typically sufficient for six-degree-of-freedom tracking, multiple base stations (e.g., base stations 214 a, 214 b) may be necessary or desired in some embodiments to provide robust room-scale tracking for HMD devices and peripherals. In this example, optical receivers are incorporated into the HMD device 202 and or other tracked objects, such as the controllers 208 and 210. In at least some implementations, optical receivers may be paired with an accelerometer and gyroscope Inertial Measurement Unit (“IMU”) on each tracked device to support low-latency sensor fusion.

In at least some implementations, each base station 214 includes two rotors which sweep a linear beam across the tracked volume 201 on orthogonal axes. At the start of each sweep cycle, the base station 214 may emit an omni-directional light pulse (referred to as a “sync signal”) that is visible to all sensors on the tracked objects. Thus, each sensor computes a unique angular location in the swept volume by timing the duration between the sync signal and the beam signal. Sensor distance and orientation may be solved using multiple sensors affixed to a single rigid body.

The one or more sensors positioned on the tracked objects (e.g., HMD device 202, controllers 208 and 210) may comprise an optoelectronic device capable of detecting the modulated light from the rotor. For visible or near-infrared (NIR) light, silicon photodiodes and suitable amplifier/detector circuitry may be used. Because the environment 200 may contain static and time-varying signals (optical noise) with similar wavelengths to the signals of the base stations 214 signals, in at least some implementations the base station light may be modulated in such a way as to make it easy to differentiate from any interfering signals, and/or to filter the sensor from any wavelength of radiation other than that of base station signals.

Inside-out tracking is also a type positional tracking that may be used to track the position of the HMD device 202 and/or other objects (e.g., controllers 208 and 210, tablet computers, smartphones). Inside-out tracking differs from outside-in tracking by the location of the cameras or other sensors used to determine the HMD's position. For inside-out tracking, the camera or sensors are located on the HMD, or object being tracked, while in outside-out tracking the camera or sensors are placed in a stationary location in the environment.

An HMD that utilizes inside-out tracking utilizes one or more cameras to “look out” to determine how its position changes in relation to the environment. When the HMD moves, the sensors readjust their place in the room and the virtual environment responds accordingly in real-time. This type of positional tracking can be achieved with or without markers placed in the environment. The cameras that are placed on the HMD observe features of the surrounding environment. When using markers, the markers are designed to be easily detected by the tracking system and placed in a specific area. With “markerless” inside-out tracking, the HMD system uses distinctive characteristics (e.g., natural features) that originally exist in the environment to determine position and orientation. The HMD system's algorithms identify specific images or shapes and use them to calculate the device's position in space. Data from accelerometers and gyroscopes can also be used to increase the precision of positional tracking.

FIG. 3 shows information 300 illustrating a front view of an example HMD device 344 when worn on the head of a user 342. The HMD device 344 includes a front-facing structure 343 that supports a front-facing or forward camera 346 and a plurality of sensors 348 a-348 d (collectively 348) of one or more types. As one example, some or all of the sensors 348 may assist in determining the location and orientation of the device 344 in space, such as light sensors to detect and use light information emitted from one or more external devices (not shown, e.g., base stations 214 of FIG. 2 ). As shown, the forward camera 346 and the sensors 348 are directed forward toward an actual scene or environment (not shown) in which the user 342 operates the HMD device 344. The actual physical environment may include, for example, one or more objects (e.g., walls, ceilings, furniture, stairs, cars, trees, tracking markers, or any other types of objects). The particular number of sensors 348 may be fewer or more than the number of sensors depicted. The HMD device 344 may further include one or more additional components that are not attached to the front-facing structure (e.g., are internal to the HMD device), such as an IMU (inertial measurement unit) 347 electronic device that measures and reports the HMD device's 344 specific force, angular rate, and/or the magnetic field surrounding the HMD device (e.g., using a combination of accelerometers and gyroscopes, and optionally, magnetometers). The HMD device may further include additional components that are not shown, including one or more display panels and optical lens systems that are oriented toward eyes (not shown) of the user and that optionally have one or more attached internal motors to change the alignment or other positioning of one or more of the optical lens systems and/or display panels within the HMD device, as discussed in greater detail below with respect to FIG. 4 .

The illustrated example of the HMD device 344 is supported on the head of user 342 based at least in part on one or more straps 345 that are attached to the housing of the HMD device 344 and that extend wholly or partially around the user's head. While not illustrated here, the HMD device 344 may further have one or more external motors, such as attached to one or more of the straps 345, and automated corrective actions may include using such motors to adjust such straps in order to modify the alignment or other positioning of the HMD device on the head of the user. It will be appreciated that HMD devices may include other support structures that are not illustrated here (e.g., a nose piece, chin strap, etc.), whether in addition to or instead of the illustrated straps, and that some embodiments may include motors attached one or more such other support structures to similarly adjust their shape and/or locations to modify the alignment or other positioning of the HMD device on the head of the user. Other display devices that are not affixed to the head of a user may similarly be attached to or part of one or structures that affect the positioning of the display device, and may include motors or other mechanical actuators in at least some embodiments to similarly modify their shape and/or locations to modify the alignment or other positioning of the display device relative to one or more pupils of one or more users of the display device.

FIG. 4 illustrates a simplified top plan view 400 of an HMD device 405 that includes a pair of near-to-eye display systems 402 and 404. The HMD device 405 may, for example, be the same or similar HMD devices illustrated in FIGS. 1-3 or a different HMD device, and the HMD devices discussed herein may further be used in the examples discussed further below. The near-to-eye display systems 402 and 404 of FIG. 4 include display panels 406 and 408, respectively (e.g., OLED micro-displays), and respective optical lens systems 410 and 412 that each have one or more optical lenses. The display systems 402 and 404 may be mounted to or otherwise positioned within a housing (or frame) 414, which includes a front-facing portion 416 (e.g., the same or similar to the front-facing surface 343 of FIG. 3 ), a left temple 418, right temple 420 and interior surface 421 that touches or is proximate to a face of a wearer user 424 when the HMD device is worn by the user. The two display systems 402 and 404 may be secured to the housing 414 in an eye glasses arrangement which can be worn on the head 422 of a wearer user 424, with the left temple 418 and right temple 420 resting over the user's ears 426 and 428, respectively, while a nose assembly 492 may rest over the user's nose 430. In the example of FIG. 4 , the HMD device 405 may be supported on the head of the user in part or in whole by the nose display and/or the right and left over-ear temples, although straps (not shown) or other structures may be used in some embodiments to secure the HMD device to the head of the user, such as the embodiments shown in FIGS. 2 and 3 . The housing 414 may be shaped and sized to position each of the two optical lens systems 410 and 412 in front of one of the user's eyes 432 and 434, respectively, such that a target location of each pupil 494 is centered vertically and horizontally in front of the respective optical lens systems and/or display panels. Although the housing 414 is shown in a simplified manner similar to eyeglasses for explanatory purposes, it should be appreciated that in practice more sophisticated structures (e.g., goggles, integrated headband, helmet, straps, etc.) may be used to support and position the display systems 402 and 404 on the head 422 of user 424.

The HMD device 405 of FIG. 4 , and the other HMD devices discussed herein, is capable of presenting a virtual reality display to the user, such as via corresponding video presented at a display rate such as 30 or 60 or 90 frames (or images) per second, while other embodiments of a similar system may present an augmented reality display to the user. Each of the displays 406 and 408 of FIG. 4 may generate light which is transmitted through and focused by the respective optical lens systems 410 and 412 onto the eyes 432 and 434, respectively, of the user 424. The pupil 494 aperture of each eye, through which light passes into the eye, will typically have a pupil size ranging from 2 mm (millimeters) in diameter in very bright conditions to as much as 8 mm in dark conditions, while the larger iris in which the pupil is contained may have a size of approximately 12 mm—the pupil (and enclosing iris) may further typically move within the visible portion of the eye under open eyelids by several millimeters in the horizontal and/or vertical directions, which will also move the pupil to different depths from the optical lens or other physical elements of the display for different horizontal and vertical positions as the eyeball swivels around its center (resulting in a three dimensional volume in which the pupil can move). The light entering the user's pupils is seen by the user 424 as images and/or video. In some implementations, the distance between each of the optical lens systems 410 and 412 and the user's eyes 432 and 434 may be relatively short (e.g., less than 30 mm, less than 20 mm), which advantageously causes the HMD device to appear lighter to the user since the weight of the optical lens systems and the display systems are relatively close to the user's face, and also may provide the user with a greater field of view. While not illustrated here, some embodiments of such an HMD device may include various additional internal and/or external sensors.

In the illustrated embodiment, the HMD device 405 of FIG. 4 further includes hardware sensors and additional components, such as to include one or more accelerometers and/or gyroscopes 490 (e.g., as part of one or more IMU units). As discussed in greater detail elsewhere herein, values from the accelerometer(s) and/or gyroscopes may be used to locally determine an orientation of the HMD device. In addition, the HMD device 405 may include one or more front-facing cameras, such as camera(s) 485 on the exterior of the front portion 416, and whose information may be used as part of operations of the HMD device, such as for providing AR functionality or positioning functionality. Furthermore, the HMD device 405 may further include other components 475 (e.g., electronic circuits to control display of images on the display panels 406 and 408, internal storage, one or more batteries, position tracking devices to interact with external base stations, etc.), as discussed in greater detail elsewhere herein. Other embodiments may not include one or more of the components 475, 485 and/or 490. While not illustrated here, some embodiments of such an HMD device may include various additional internal and/or external sensors, such as to track various other types of movements and position of the user's body, eyes, controllers, etc.

In the illustrated embodiment, the HMD device 405 of FIG. 4 further includes hardware sensors and additional components that may be used by disclosed embodiments as part of the described techniques for determining user pupil or gaze direction, which may be provided to one or more components associated with the HMD device for use thereby, as discussed elsewhere herein. The hardware sensors in this example include one or more eye tracking assemblies 472 of an eye tracking subsystem that are mounted on or near the display panels 406 and 408 and/or located on the interior surface 421 near the optical lens systems 410 and 412 for use in acquiring information regarding the actual locations of the user's pupils 494, such as separately for each pupil in this example.

Each of the eye tracking assemblies 472 may include one or more light sources (e.g., IR LEDs) and one or more light detectors (e.g., silicon photodiodes). Further, although only four total eye tracking assemblies 472 are shown in FIG. 4 for clarity, it should be appreciated that in practice a different number of eye tracking assemblies may be provided. In some embodiments, a total of eight eye tracking assemblies 472 are provided, four eye tracking assemblies for each eye of the user 424. Further, in at least some implementations, each eye tracking assembly includes a light source directed at one of the user's 424 eyes 432 and 434, a light detector positioned to receive light reflected by the respective eye of the user, and a polarizer positioned and configured to prevent light that is reflected via specular reflection from being imparted on the light detector.

As discussed in greater detail elsewhere herein, information from the eye tracking assemblies 472 may be used to determine and track the user's gaze direction during use of the HMD device 405. Furthermore, in at least some embodiments, the HMD device 405 may include one or more internal motors 438 (or other movement mechanisms) that may be used to move 439 the alignment and/or other positioning (e.g., in the vertical, horizontal left-and-right and/or horizontal front-and-back directions) of one or more of the optical lens systems 410 and 412 and/or display panels 406 and 408 within the housing of the HMD device 405, such as to personalize or otherwise adjust the target pupil location of one or both of the near-to-eye display systems 402 and 404 to correspond to the actual locations of one or both of the pupils 494. Such motors 438 may be controlled by, for example, user manipulation of one or more controls 437 on the housing 414 and/or via user manipulation of one or more associated separate I/O controllers (not shown). In other embodiments the HMD device 405 may control the alignment and/or other positioning of the optical lens systems 410 and 412 and/or display panels 406 and 408 without such motors 438, such as by use of adjustable positioning mechanisms (e.g., screws, sliders, ratchets, etc.) that are manually changed by the user via use of the controls 437. In addition, while the motors 438 are illustrated in FIG. 4 for only one of the near-to-eye display systems, each near-to-eye display system may have its own one or more motors in some embodiments, and in some embodiments one or more motors may be used to control (e.g., independently) each of multiple near-to-eye display systems.

While the described techniques may be used in some embodiments with a display system similar to that illustrated, in other embodiments other types of display systems may be used, including with a single optical lens and display device, or with multiple such optical lenses and display devices. Non-exclusive examples of other such devices include cameras, telescopes, microscopes, binoculars, spotting scopes, surveying scopes, etc. In addition, the described techniques may be used with a wide variety of display panels or other display devices that emit light to form images, which one or more users view through one or more optical lens, as discussed elsewhere herein. In other embodiments, the user may view one or more images through one or more optical lens that are produced in manners other than via a display panel, such as on a surface that reflects light from another light source (e.g. laser scan beam) in part or in whole.

Example Display Systems

FIG. 5 is a schematic block diagram of a display system 500 according to one non-limiting illustrated implementation. The display system may 500 may be a display system of a head-mounted display system, such as the head-mounted display systems discussed above, or any other type of display system (e.g., wearable or non-wearable display system). The display system 500 may include a scan beam display system or another type of display system (e.g., micro-display). In at least some implementations, the display system 500 may be one of two substantially identical display systems provided in a device, such as a head-mounted display device.

The display system 500 includes a display light source 502 that is optically coupled to a pupil relay system 504. The display light source 502 may include a laser scan beam light source, a micro-display, or any other suitable display light source. The pupil relay system 504 is positioned to relay a first pupil from the display light source 502 to a second pupil at an eye 506 of a viewer (or other image plane, surface, or material). The pupil relay system 504 includes a polarization sensitive optic 508 (e.g., a post-scan optic), which may include one or more of a waveguide-based optical system, a pancake optical system, a birdbath optical system, a coating-based optical system, or other optics. The polarization sensitive optic 508 may include one more components. The efficiency of the polarization sensitive optic 508 may be very sensitive to the polarization of light that passes therethrough. That is, different polarizations will significantly change the intensity and stray light that makes it out of the polarization sensitive optic 508.

To optimize the polarization of light that is provided to the polarization sensitive optic 508, the pupil relay system 504 of the display system 500 further includes a spatially varying polarizer 510 having a polarization that spatially varies as a function of position, which functions to compensation for changes in polarization to provide uniform polarized light or, more generally optimized polarized light, to the polarization sensitive optic 508. For example, the polarization sensitive optic 508 may be configured to compensate for or “undo” any of the polarization that one or more mirrors or other optics generate from compound angles. As discussed further below, the spatially varying polarizer 510 may be selectively adjusted in real-time to provide optimized performance in a region or field of view based on the user's gaze location.

The spatially varying polarizer 510 may include a wave retarder that is formed of birefringent materials. Birefringence is the property of a material that has a refractive index that depends on the polarization and propagation direction of light. The wave retarder alters the polarization state or phase of light traveling through the wave retarder. The wave retarder may have a slow axis (or extraordinary axis) and a fast axis (ordinary axis). As polarized light travels through the wave retarder, the light along the fast axis travels more quickly than along the slow axis.

As discussed above, the spatially varying polarizer 510 may provide phase retardation that varies a function of position, e.g., horizontal position, vertical position, radial position, across a field of view (e.g., on-axis to off-axis) which allows for more uniform and efficient distribution of the light from the display light source 502 to the polarization sensitive optic 508. The particular manner in which the retardation of the spatially varying polarizer 510 varies may be dependent on the specific configuration and materials of the optical system(s) of the display system 500, such as the polarization state of incident light, incident angle(s), materials, geometry of various components, etc.

As an example, the spatially varying polarizer 510 may provide no retardation at a first position, and may linearly increase the retardation to provide a retardation of λ/4 (or other value) at a second position of the spatially varying polarizer. Generally, the spatially varying polarizer 510 may provide retardation that varies in any way as a function of position, and the amounts of retardation may be any value (e.g., λ/20, λ/10, λ/4, λ, 2λ). Further, the amount of retardation may increase only in one or more directions, decrease only in one or more directions, or both increase and decrease. The amount of retardation may vary continuously, or may vary in a number of steps. The amount of retardation may vary according to any type of function including, for example, linear functions, polynomial functions, exponential functions, step functions, other types of functions, or combinations thereof.

In at least some implementations, the spatially varying polarizer 510 may be formed of a multi-twist retarder (MTR), which is a waveplate-like retardation film that provides precise and customized levels of broadband, narrowband or multiple band retardation in a single thin film. More specifically, MTR comprises two or more twisted liquid crystal (LC) layers on a single substrate and with a single alignment layer. Subsequent LC layers are aligned directly by prior layers, allowing simple fabrication, achieving automatic layer registration, and resulting in a monolithic film with a continuously varying optic axis.

FIG. 6 is a schematic diagram of a scan beam display system or projector 600, according to one non-limiting illustrated implementation. The scan beam display system 600 includes a light source 602, which may be a laser light source that emits a beam 604. The light source 602 may include two more light sources, such as a red light source, a green light source, and a blue light source. In such instances, the plurality of light sources may be combined into a single beam by a beam combiner. In at least some implementations, the light source 602 may include one or more color light sources (e.g., red, green, blue) and a light source that emits an invisible beam, such as an infrared beam or an ultraviolet beam, which may be used for various purposes such as eye tracking. The beam 604 is incident on a scanning platform 606, which may include a microelectromechanical system (MEMS) based scanner, and reflects off of a scan mirror 608 of the platform to generate a controlled output beam 610. The scanning platform 606 may include a diffractive optical grating, a moving optic grating, a light valve, a rotating mirror, a movable silicon device, a digital light projector device, a flying spot projector, a liquid crystal on silicon (LCoS) device, or other scanning or modulating devices. The scanning platform 606 may be coupled to one or more drive circuits that are selectively controlled by a controller 612 coupled to the scanning platform and the light source 602, which may comprise any suitable control circuitry having one more components. The drive circuitry modulates the direction in which the scanning mirror 608 deflects the incident beam 604 to cause the output beam 610 to generate a scan, such as a raster scan, thereby creating a displayed image on an image plane such as a display surface or a viewer's eye 614.

FIG. 7 is a schematic diagram of a scan beam display system or projector 700 according to one non-limiting illustrated implementation. The scan beam display system 700 may be similar or identical to the scan beam display system 600 of FIG. 6 in many respects. As such, like components are referenced with the same numerals and a discussion of such components is not repeated herein for the sake of brevity.

The scan beam display system 700 includes post-scan correction optics 702 (“post-scan optics”) and collimation optics 704. The post-scan optics 702 may include one or more optics positioned in the light path after the scanning platform 606, which may generally be referred to herein as being “post-scan.” The post-scan correction optics 702 may be designed and configured to correct or adjust one or more distortion artifacts in the projected image. Examples of such distortion may include smile distortion, pin cushion distortion, barrel distortion, off-axis projection-based distortion, etc. It should be appreciated that these are only non-limiting example types of distortion that the post-scan correction optics 702 may correct.

The post-scan optics 702 may include one or more of a waveguide-based optical system, a pancake optical system, a birdbath optical system, a coating-based optical system, etc. The post-scan optics may include one more components. The efficiency of the post-scan optics 702 may be very sensitive to the polarization of light that passes therethrough. That is, different polarizations will significantly change the intensity and stray light that makes it out of the post-scan optics 702. In at least some implementations, the display system 700 may also include collimating or beam forming optics 704 that may be utilized to at least partially regain loss of the infinite focus caused by the post-scan optics 702.

The display system 700 further includes a polarization compensation optic in the form of a spatially varying polarizer 706 positioned between the scan mirror 608 and the post-scan optics 702 to provide polarization compensation for the post-scan optics 702 which, as discussed above may be very polarization sensitive. The spatially varying polarizer 706 may be positioned on, adjacent to, or inside the post-scan optics 702, for example. In other implementations, the spatially varying polarizer 706 is positioned elsewhere in the optical path between the light source 602 and the displayed image (e.g., pre-scan, post-scan, adjacent the light source, etc.).

In at least some implementations, the controller 612 may be operatively coupled to the spatially varying polarizer 706 to selectively vary the spatially-dependent phase retardation of the spatially varying polarizer to any desired configuration. In such implementations, one or more thin-film transistor layers may be provided that allow the spatially-dependent phase retardation of the spatially varying polarizer 706 to be selectively controlled by the controller 612. The controller 612 may control the phase retardation at any desired rate, such as one time only, periodically, at a rate that is equal to a frame rate of the display system 700 or a fraction thereof, etc.

In at least some implementations, the controller 612 may be operative to receive gaze tracking information 708, which may be used to selectively adjust the spatially-dependent phase retardation of the spatially varying polarizer 706 to be optimized in an optimized region where the user is believed to be currently gazing. Such gaze tracking information may be received from an eye tracking subsystem, from information about the content being displayed (e.g., objects of focus), or from any other source that provides information relating to where on a display the user is likely to be gazing.

As noted above, the efficiency of the post-scan optics 702 may be very sensitive to the polarization of light that passes therethrough. That is, different polarizations will significantly change the intensity and stray light that makes it out of the post-scan optics 702. It may be advantageous to optimize the spatially varying polarizer 706 over a relatively small region or field of view (e.g., 0-10 degrees, 0-30 degrees, other region), which may provide significantly better performance than optimizing over the entire field of view. Using gaze tracking information, the system may optimize a region for various characteristics (e.g., intensity, stray light) while configuring areas outside of the region to have lower performance (e.g., less intensity, more stray light). Since the user's vision is not as discerning in peripheral regions, the user may not even perceive that the performance of the display is reduced outside of the region in which the user is gazing.

FIG. 8 is a schematic diagram of a display system 800 that includes a waveguide-based optical system and a polarization compensation optic in the form of a spatially varying polarizer for use in a head-mounted display system, according to one non-limiting illustrated implementation. The display system 800 may include a lens or support structure 802 (e.g., prescription or non-prescription eye glasses lens). A waveguide structure 804 may be at least partially embedded in the structure 802 or positioned proximate to the structure (e.g., in front of or behind the structure). The waveguide 804 may be a rectangular (or other shape) prism structure formed of a material having an index of refraction that is sufficiently different from that of a surrounding structure (e.g., structure 802) to provide total internal reflection within the waveguide.

To enable light to couple into the waveguide 804, the display system 800 includes an in-coupler 806 physically coupled to a first portion of the waveguide. Similarly, to enable light to couple out of the waveguide 804 toward an eye 810 of the viewer, the display system 800 includes an out-coupler 808 physically coupled to a second portion of the waveguide. The display light that in-couples through the in-coupler 806 and out-couples through the out-coupler 808 may originate from a display light source, such as a projector, a scanning laser projector, a micro display, or other display light source, as discussed above. As non-limiting examples, the couplers 806 and 808 may include one or more of diffraction gratings, holograms, holographic optical elements, volume diffraction gratings, surface relief diffraction gratings, etc. The couplers 806 and 808 may also be reflection-type couplers or transmission-type couplers. As an example, the structure 802 may include a right eye glasses lens, and the in-coupler 806 may be positioned near the edge of the eyeglasses lens proximate a display source (e.g., projector), and the out-coupler may be positioned toward the center of the eyeglasses lens so that the viewer can see the light from the waveguide 804 while looking straight area or approximately straight ahead.

The display system 800 further includes a polarization compensation optic in the form of a spatially varying polarizer 812. In the non-limiting illustrated example, the spatially varying polarizer 812 is positioned adjacent the in-coupler 806 to provide polarization compensation for light that enters the waveguide 804 which, as discussed above may be very polarization sensitive. The spatially varying polarizer 812 may be positioned on, adjacent to, or inside (as shown in dashed lines) the waveguide 804, for example. In at least some implementations, the spatially varying polarizer 812 is positioned adjacent either side of the in-coupler 806 or the out-coupler 808, for example. In other implementations, the spatially varying polarizer 812 is positioned elsewhere in the optical path between the display light source and the eye of the viewer to provide polarization compensation.

FIG. 9 is a schematic diagram of a display system 900 that for an augmented reality system that utilizes polarization multiplexing to provide a waveguide structure that is optimized over wavelength (e.g., color). The display system 800 includes some components that are similar or identical to the components of the display system 800, which components are identified by the same reference numerals. The display system 900 may include a lens or support structure 802 (e.g., prescription or non-prescription eye glasses lens). An optical combiner structure 902 may be at least partially embedded in the structure 802 (e.g., lens) or positioned proximate to the structure (e.g., in front of or behind the structure). The optical combiner 902 may be a rectangular (or other shape) structure formed of a material having an index of refraction that is sufficiently different from that of a surrounding structure (e.g., structure 802) to provide total internal reflection within at least part of the optical combiner.

To enable light to couple into the optical combiner 902, the display system 900 includes an in-coupler 806 physically coupled to a first portion of the optical combiner 902. Similarly, to enable light to couple out of the optical combiner 902 toward an eye 810 of the viewer, the display system 900 includes an out-coupler 808 physically coupled to a second portion of the optical combiner opposite the first portion. The display light that in-couples through the in-coupler 806 and out-couples through the out-coupler 808 may originate from an optical engine 908, which may include a display light source 910, such as a projector, a scanning laser projector, a micro display, or other display light source, as discussed above. As non-limiting examples, the couplers 806 and 808 may include one or more of diffraction gratings, holograms, holographic optical elements, volume diffraction gratings, surface relief diffraction gratings, etc. The couplers 806 and 808 may also be reflection-type couplers or transmission-type couplers. As an example, the structure 802 may include a right eye glasses lens, and the in-coupler 806 may be positioned near the edge of the eyeglasses lens proximate a display source (e.g., projector), and the out-coupler may be positioned toward the center of the eyeglasses lens so that the viewer can see the light from the optical combiner 902 while looking straight area or approximately straight ahead. Further, in at least some implementations, the components shown in FIG. 9 may be for one eye of the user, and a set of similar or identical components may be provided for the other eye of the user to provide a binocular display.

In the illustrated example, the optical engine 908 includes a selective polarizer optic (SPO) 912 positioned in front of the light source 910 (e.g., micro display, scan beam). The selective polarizer optic 912 may be formed of a liquid crystal material, such as a multi-twist retarder (MTR) discussed above, and may be similar or identical to the spatially varying polarizers discussed elsewhere herein. In general, light from the display source that exits the selective polarizer optic is collimated by a collimator 914, and then interacts with the in-coupler 806 to be guided by the optical combiner 902. The optical combiner 902 provide optical correction and conveys the light to the out-coupler 808, where the light 920 exits the optical combiner 902 and presents an image to the eye 810 of the user.

More particularly, the selective polarizer optic 912 receives light 916 that includes multiple wavelengths or colors C1, C2, C3 (e.g., red, green, blue). The selective polarizer optic 912 is operative to receive the light 916 from the display light source 910, and to output light 918 of a first color (C1) in a first polarization state (P1) and light of at least a second color (C2 or C3) in a second polarization state (P2), the second polarization state orthogonal to the first polarization state. As an non-limiting example, the selective polarizer optic 912 may convert red light (C1) into the p polarization state (P1), and may convert green (C2) and blue (C3) light into the s polarization state (P2).

The optical combiner 902 includes a first polarization sensitive diffractive optical element (PSDOE) 904 and a second polarization sensitive diffractive optical element 906. Each of the first and second polarization sensitive diffractive optical elements may be formed from a liquid crystal material, such as a multi-twist retarder, and may be similar or identical to the spatially varying polarizers discussed elsewhere herein. The first polarization sensitive diffractive optical element 904 includes a first diffraction pattern that diffracts light of the first polarization state (P1) and passes light of the second polarization state (P2) without diffraction. Similarly, the second polarization sensitive diffractive optical element 906 includes a second diffraction pattern that diffracts light of the second polarization state (P2) and passes light of the first polarization state (P1) without diffraction. The first diffractive pattern is designed to provide optimized correction for the first color (C1), and the second diffractive pattern is designed to provide optimized correction for at least the second color (e.g., C2 and or C3).

As discussed above, it can be difficult to design a diffractive optical element that provides acceptable correction over all of the desired wavelengths (e.g., 380 to 740 nanometers). By polarizing the light from the light source 910 dependent on color, each of the first and second polarization sensitive diffractive optical elements 904 and 906 can be optimized for a narrower range of wavelengths, which allows for more design freedom and ultimately better correction by the overall optical combiner 902. Continuing with the example above, the first polarization sensitive diffractive optical element 904 may be optimized for only red light (C1) in the first polarization state (P1) since the first polarization sensitive diffractive optical element won't see green or blue light which is in the second polarization state (P2). Likewise, the second polarization sensitive diffractive optical element 906 may be optimized for only green light (C2) and blue light (C3) in the second polarization state (P2) since the second polarization sensitive diffractive optical element won't see red light (C1) which is in the first polarization state (P1).

FIG. 10 is a schematic diagram of a display system 1000 that for an augmented reality system that utilizes polarization multiplexing to provide a waveguide structure that is optimized over a total or overall field of view of the display system. The display system 1000 includes some components that are similar or identical to the components of the display systems discussed above, which components are identified by the same reference numerals. The display system 1000 may include a lens or support structure 802 (e.g., prescription or non-prescription eye glasses lens). An optical combiner structure 1002 may be at least partially embedded in the structure 802 (e.g., lens) or positioned proximate to the structure (e.g., in front of or behind the structure). The optical combiner 1002 may be a rectangular (or other shape) structure formed of a material having an index of refraction that is sufficiently different from that of a surrounding structure (e.g., structure 802) to provide total internal reflection within at least part of the optical combiner.

To enable light to couple into the optical combiner 1002, the display system 1000 includes an in-coupler 806 physically coupled to a first portion of the optical combiner 1002. Similarly, to enable light to couple out of the optical combiner 1002 toward an eye 810 of the viewer, the display system 1000 includes an out-coupler 808 physically coupled to a second portion of the optical combiner opposite the first portion. The display light that in-couples through the in-coupler 806 and out-couples through the out-coupler 808 may originate from an optical engine 1008, which may include a display light source 1010, such as a projector, a scanning laser projector, a micro display, or other display light source, as discussed above. As non-limiting examples, the couplers 806 and 808 may include one or more of diffraction gratings, holograms, holographic optical elements, volume diffraction gratings, surface relief diffraction gratings, etc. The couplers 806 and 808 may also be reflection-type couplers or transmission-type couplers. As an example, the structure 802 may include a right eye glasses lens, and the in-coupler 806 may be positioned near the edge of the eyeglasses lens proximate a display source (e.g., projector), and the out-coupler may be positioned toward the center of the eyeglasses lens so that the viewer can see the light from the optical combiner 1002 while looking straight area or approximately straight ahead. Further, in at least some implementations, the components shown in FIG. 10 may be for one eye of the user, and a set of similar or identical components may be provided for the other eye of the user to provide a binocular display.

In the illustrated example, the optical engine 1008 includes a selective polarizer optic (SPO) 1012 positioned in front of the light source 1010 (e.g., micro display, scan beam). The selective polarizer optic 1012 may be formed of a liquid crystal material, such as a multi-twist retarder (MTR). In general, light from the display source that exits the selective polarizer optic 1012 is collimated by a collimator 1014, and then interacts with the in-coupler 806 to be guided by the optical combiner 1002. The optical combiner 1002 provide optical correction and conveys the light to the out-coupler 808, where the light 1020 exits the optical combiner 1002 and presents an image to the eye 810 of the user.

More particularly, the selective polarizer optic 1012 receives light 1016 that includes multiple wavelengths or colors C1, C2, C3 (e.g., red, green, blue) that spans a total or overall field of view that is to be provided to the eye 810 of the user. The selective polarizer optic 1012 is operative to receive the light 1016 from the display light source 1010, and to output light 1018 within a first field of view portion (FOV1) in a first polarization state (P1) and light 1019 in a second field of view portion (FOV2) in a second polarization state (P2), the second polarization state orthogonal to the first polarization state. As an non-limiting example, the selective polarizer optic 1012 may convert light that is on axis and within a narrow angular range (e.g., within 20 degrees from on axis) into the p polarization state (P1), and may convert light that is in the overall field of view outside of the narrow angular range into the s polarization state (P2). FIG. 11A shows an example total field of view 1100 of an HMD system that is comprised of a first field of view portion 1102 with a narrow angular range surrounded by a second field of view portion 1104. FIG. 11B shows another example of a total field of view 1100 that is comprised of a first field of view portion 1106 positioned adjacent a second field of view portion 1108. It should be appreciated that the illustrated embodiments are provided by way of example only, and other configurations of first and second field of view portions may be used.

The optical combiner 1002 includes a first polarization sensitive diffractive optical element (PSDOE) 1004 and a second polarization sensitive diffractive optical element 1006. Each of the first and second polarization sensitive diffractive optical elements may be formed from a liquid crystal material, such as a multi-twist retarder. The first polarization sensitive diffractive optical element 1004 includes a first diffraction pattern that diffracts light of the first polarization state (P1) and passes light of the second polarization state (P2) without diffraction. Similarly, the second polarization sensitive diffractive optical element 1009 includes a second diffraction pattern that diffracts light of the second polarization state (P2) and passes light of the first polarization state (P1) without diffraction. The first diffractive pattern is designed to provide optimized correction for the first field of view portion (FOV1), and the second diffractive pattern is designed to provide optimized correction for the second field of view portion (FOV2).

As discussed above, it can be difficult to design a diffractive optical element that provides acceptable correction over an entire field of view of a display system. By polarizing the light from the light source 1010 dependent on field of view portions of an overall field of view, each of the first and second polarization sensitive diffractive optical elements 1004 and 1006 can be optimized for a smaller field of view, which allows for more design freedom and ultimately better correction by the overall optical combiner 1002. Continuing with the example above, the first polarization sensitive diffractive optical element 1004 may be optimized for only a narrow field of view (FOV1) in the first polarization state (P1) since the first polarization sensitive diffractive optical element won't see light in the broad field of view (FOV2) which is in the second polarization state (P2). Likewise, the second polarization sensitive diffractive optical element 1006 may be optimized for only light in the broad field of view (FOV2) in the second polarization state (P2) since the second polarization sensitive diffractive optical element won't see light in the narrow field of view (FOV1) which is in the first polarization state (P1).

In at least some implementations, a controller (e.g., controller 612) may be operatively coupled to the selective polarizer optics and/or the polarization sensitive diffractive optical elements to selectively vary their spatially-dependent phase retardation to any desired configuration. In such implementations, one or more thin-film transistor layers may be provided that allow the spatially-dependent phase retardation of the components to be selectively controlled. The controller may control the phase retardation at any desired rate, such as one time only, periodically, at a rate that is equal to a frame rate of the display system or a fraction thereof, etc.

By utilizing the spatially varying polarizers discussed herein, optical designers have significantly more degrees of freedom to produce optical systems that have improved performance and efficiency, which allows for display systems that provide a better viewing experience, cost less, are smaller in size or weight, consume less power, and provide other advantages that will be apparent to those skilled in the art.

The various implementations described above can be combined to provide further implementations. These and other changes can be made to the implementations in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific implementations disclosed in the specification and the claims, but should be construed to include all possible implementations along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure. 

The invention claimed is:
 1. A head-mounted display system, comprising: a support structure; and a display system coupled to the support structure, the display system comprising: a display light source; a selective polarizer optic operative to receive light from the display light source, and to output light of a first color in a first polarization state and light of a second color in a second polarization state, the second polarization state orthogonal to the first polarization state; and an optical combiner positioned to receive light from the selective polarizer optic and to provide images to an eye of a viewer, the optical combiner comprising: a first polarization sensitive diffractive optical element (PSDOE) that includes a first diffraction pattern that diffracts light of the first polarization state and passes light of the second polarization state without diffraction, the first diffractive pattern providing optimized correction for the first color; and a second PSDOE that includes a second diffraction pattern that diffracts light of the second polarization state and passes light of the first polarization state without diffraction, the second diffractive pattern providing optimized correction for the second color.
 2. The head-mounted display system of claim 1 wherein each of the selective polarizer optic, the first PSDOE, and the second PSDOE comprises a multi-twist retarder.
 3. The head-mounted display system of claim 1 wherein at least one of the selective polarizer optic, the first PSDOE, and the second PSDOE comprise a multi-twist retarder.
 4. The head-mounted display system of claim 1 wherein at least one of the selective polarizer optic, the first PSDOE, and the second PSDOE comprise liquid crystal material.
 5. The head-mounted display system of claim 1 wherein a selective polarizer optic is operative to output light of a third color in the second polarization state, and the second diffractive pattern provides optimized correction for the second color and the third color.
 6. The head-mounted display system of claim 5 wherein the first color is red and the second and third colors are green and blue, respectively.
 7. The head-mounted display system of claim 1 wherein the first color is red, and the second color is green or blue.
 8. The head-mounted display system of claim 1 wherein the optical combiner comprises an in-coupler and an out-coupler.
 9. The head-mounted display system of claim 1 wherein the support structure comprises an eyeglasses lens.
 10. The head-mounted display system of claim 1 wherein the display light source comprises a laser scan beam system or a micro-display. 